Mouse with improved input mechanisms

ABSTRACT

A mouse having improved input methods and mechanisms is disclosed. The mouse is configured with touch sensing areas capable of generating input signals. The touch sensing areas may for example be used to differentiate between left and right clicks in a single button mouse. The mouse may further be configured with force sensing areas capable of generating input signals. The force sensing areas may for example be positioned on the sides of the mouse so that squeezing the mouse generates input signals. The mouse may further be configured with a jog ball capable of generating input signals. The mouse may additionally be configured with a speaker for providing audio feedback when the various input devices are activated by a user.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is related to the following applications, which are allherein incorporated by reference:

U.S. Pat. No.: 6,373,470, titled, “CURSOR CONTROL DEVICE HAVING ANINTEGRAL TOP MEMBER,” issued Apr. 16, 2002;

U.S. patent application Ser. No.: 10/209,537, titled “MULTI-BUTTONMOUSE,” filed on Jul. 30, 2002;

U.S. patent application Ser. No.: 10/060,712, titled “CURSOR CONTROLDEVICE HAVING AN INTEGRAL TOP MEMBER,” filed on Jan. 29, 2002;

U.S. patent application Ser. No.: 10/072,765, titled “MOUSE HAVING AROTARY DIAL,” filed on Feb. 7, 2002;

U.S. patent application Ser. No.: 10/238,380, titled “MOUSE HAVING ANOPTICALLY-BASED SCROLLING FEATURE,” filed on Sep. 9, 2002;

U.S. patent application Ser. No.: 10/157,343, titled “MOUSE HAVING ABUTTON-LESS PANNING AND SCROLLING SWITCH,” filed on May 28, 2002; and

U.S. patent application Ser. No.: 10/654,108, titled “AMBIDEXTROUSMOUSE,” filed on Sep. 2, 2003.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates generally to mice. More particularly, thepresent invention relates to a mouse including improved inputmechanisms.

2. Description of the Related Art

Most computer systems, as for example general purpose computers such asportable computers and desktop computers, receive input from a user viaan input device such as a mouse. As is generally well known, the mouseallows a user to move an input pointer and to make selections in agraphical user interface (GUI). The mouse generally includes atrackball, which is located on the underside of the mouse and whichrolls when the mouse moves thus translating the motion of the users handinto signals that the computer system can use. The movement of thetrackball generally corresponds to the movement of the input pointer inthe GUI. That is, by positioning the mouse on a desktop and moving itthereon, the user can move the input pointer in similar directions inthe GUI. An optical sensor may alternatively used to track the movementof the mouse.

Conventional mice also include one or two mechanical buttons for dataselection and command execution. The mechanical buttons are disposednear the top front portion of the mouse where they are easily accessibleto a users fingers. In some mice, a single mechanical button is placedin the middle of the mouse while in other mice, two mechanical buttonsare placed on the left and right side of the mouse. In either case, themechanical buttons typically include button caps that pivot relative toa fixed top back portion of the mouse in order to provide a mechanicalclicking action. When pressed, the button caps come down on switcheslocated underneath the button caps thereby generating button eventsignals. The mice may additionally include a scroll wheel. The scrollwheel allows a user to move through documents by simply rolling thewheel forward or backward. The scroll wheel is typically positionedbetween the right and left mechanical buttons at the front top portionof the mouse.

The unibody mouse is another type of mouse. Unlike the conventionalmouse, the unibody mouse does not include any mechanical buttons therebymaking it more elegant than the conventional mouse (e.g., no surfacebreaks or lines). The unibody mouse includes a base and a top memberthat acts like a button and that forms the entire top surface of themouse. The top member pivots relative to the base in order to provide aclicking action. In most cases, the top member moves around a pivotlocated towards the back of the mouse so that the top member can pivotforward and downward. When pivoted in this manner, the top memberactivates a switch, which causes the microcontroller in the mouse tosend a button event signal to the host computer. Although this design ismore elegant than the conventional mouse that includes mechanicalbuttons, in most cases it only operates as a single button mouse therebylimiting its functionality. The Apple Mouse manufactured by AppleComputer, Inc., of Cupertino, Calif. is one example of a unibody mouse.

Recently, dual button functionality has been implemented in a unibodymouse. In this implementation, the pivot of the top member runs throughthe middle of the mouse. This allows the top member to rock left andright. Switches are located in both the left and right positions toimplement right and left buttons. That is, moving the top member to theright causes a right click to be generated and moving the top member tothe left causes a left click to be generated. Unfortunately, the middlepivot does not allow a user to press the middle of the mouse and furtherthe force needed to activate the buttons is high at areas near themiddle pivot, and low at areas further away from the middle pivot. Thepivoting action therefore feels sloppy and non uniform, which leaves anegative impression on the user. In addition, accidental activation ofthe buttons may be encountered when the mouse is moved around, i.e., theforce used to move the mouse may cause the mouse to tilt to the right orleft. Moreover, the form factor is different than other mice which clickdown in the forward direction and therefore clicking the mouse is notintuitive to the user.

Based on the foregoing, mice with improved form, feel and functionalityare therefore desired.

SUMMARY OF THE INVENTION

The invention relates, in one embodiment, to a mouse. The mouse includesa housing and a plurality of button zones on the surface of the housing.The button zones represent regions of the housing that are capable ofdetecting touch events that occur on the surface of the housing in theregion of the button zones.

The invention relates, in another embodiment, to a mouse. The mouseincludes a mouse housing having an outer member. The mouse also includesa first touch sensor configured to sense the presence of an object at afirst region of the outer member. The mouse further includes a secondtouch sensor configured to sense the presence of an object at a secondregion of the outer member, the second region being different than thefirst region. The mouse additionally includes a sensor managementcircuit (e.g., microcontroller or other integrated circuit) thatmonitors the touch signals output by the first and second touch sensorsand reports button events based at least in part on the signals outputby the first and second touch sensors.

The invention relates, in one embodiment, to a configurable mousecapable of operating as a single button or multi-button mouse. The mouseincludes an internal switch that generates an activation signal. Themouse also includes a single moving member that provides a clickingaction. The moving member activates the internal switch during theclicking action. The mouse further includes a touch sensing arrangementthat generates a first touch signal when the movable member is touchedin a first region and a second touch signal when the movable member istouched in a second region. The signals of the internal switch and thetouch sensing arrangement indicating one or more button events of themouse.

The invention relates, in one embodiment, to a mouse. The mouse includesa housing having one or more pressure sensitive areas. The mouse alsoincludes a force sensing device located behind each of the pressuresensitive areas. The force sensing devices being configured to measurethe force exerted at the pressure sensitive areas.

The invention relates, in one embodiment, to a mouse. The mouse includesa jog ball device positioned at a surface of the mouse. The jog balldevice includes a ball that spins within a sealed housing. The ball hasa diameter that is less than 10 mm.

The invention relates, in one embodiment, to a unibody mouse including abase and a movable top member. The unibody mouse includes a base havinga first wing located on a right side of the mouse, and a second winglocated on a left side of the mouse. The unibody mouse also includes amovable top member coupled to the base. The unibody mouse furtherincludes a first touch sensor located on a front left side of the topmember and a second touch sensor located on a front right side of thetop member. The first touch sensor generates a first touch signal whenthe front left side of the top member is touched, and the second touchsensor generates a second touch signal when the front right side of thetop member is touched. The unibody mouse additionally includes a jogball device located in a front middle portion of the top member betweenthe first and second touch sensors. The jog ball device includes a ballconfigured to generate multidirectional motion signals when the ball isspun within a sealed housing. The jog ball device includes a switchconfigured to generate a first activation signal when the ball is movedrelative to the sealed housing. The unibody mouse further includes afirst force sensor located behind the first wing, and a second forcesensor located behind the second wing. The first force sensor generatesa force signal when increased pressure is exerted on the first wing, andthe second force sensor generates a force signal when increased pressureis exerted on the second wing. The unibody mouse additionally includesan internal switch configured to generate a second activation signalwhen the top member is moved relative to the base and a position sensingdevice configured to generate tracking signals when the mouse is movedalong a surface. Moreover, the unibody mouse includes a microcontrollerthat monitors all the signals of the above mentioned devices and reportstracking and multiple button events based at least in part on thesesignals solely or in combination with one another.

The invention relates, in another embodiment to a mouse. The mouseincludes an electronically controlled feedback system configured toprovide feedback to the user of the mouse so that the user is able topositively confirm that an action has resulted in an actual activationof one or more input mechanisms of the mouse.

The invention relates, in another embodiment to a mouse method. Themouse method includes monitoring pressure at the surface of a mouse. Themethod also includes performing an action based on a change in pressureat the surface of the mouse.

The invention relates, in another embodiment to a mouse method. Themethod includes monitoring a force at a surface of a mouse. The methodalso includes determining whether the mouse has been lifted off asurface. The method further includes if the mouse has not been liftedoff the surface, determining if a first force threshold has beenexceeded, and reporting a button event signal when the force is abovethe first force threshold. The method additionally includes if the mousehas been lifted off the surface, determining if a second force thresholdhas been exceeded, and reporting the button event signal when the forceis above the second force threshold.

The invention relates, in another embodiment to a mouse method. Themouse method includes monitoring pressure at mouse surface. The methodalso includes determining if a squeeze gesture is performed. The methodfurther includes if a squeeze gesture is performed, performing an actionin a window management program based on the pressure at the mousesurface.

The invention relates, in another embodiment to a mouse method. Themouse method includes monitoring a left touch sensor, a right touchsensor and a switch. The mouse method also includes reporting a leftbutton event when only the left sensor and switch are activated. Themethod further includes reporting a right button event when only theright sensor and switch are activated. The method additionally includesreporting a button event when the right sensor, left sensor and switchare activated, the button event being selected from a left button event,a right button event, a third button event, or simultaneous left andright button events.

The invention relates, in another embodiment to a mouse method. Themouse method includes detecting a touch at a surface of a mouse. Themethod also includes differentiating whether the touch is a light orhard touch. The method further includes performing a first action when atouch is a light touch. The method additionally includes performing asecond action when a touch is hard touch.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention may best be understood by reference to the followingdescription taken in conjunction with the accompanying drawings inwhich:

FIG. 1 is a perspective diagram of a mouse, in accordance with oneembodiment of the present invention.

FIG. 2 is a side elevation view, in cross section, of a mouse, inaccordance with one embodiment of the present invention.

FIG. 3 is a bottom view of a top member of a mouse, in accordance withone embodiment of the present invention.

FIG. 4 is a mouse method, in accordance with one embodiment of thepresent invention.

FIG. 5 is a mouse method, in accordance with one embodiment of thepresent invention.

FIG. 6 is a mouse vocabulary table, in accordance with one embodiment ofthe present invention.

FIG. 7 is a side view of a mouse, in accordance with one embodiment ofthe present invention.

FIG. 8 is a front view, in cross section, of a mouse, in accordance withone embodiment of the present invention.

FIG. 9 is a front view, in cross section, of a mouse, in accordance withone embodiment of the present invention.

FIG. 10 is a mouse method, in accordance with one embodiment of thepresent invention.

FIG. 11 is a graph illustrating resistance verses force, in accordancewith one embodiment of the present invention.

FIG. 12 is a block diagram of a force sensing circuit, in accordancewith one embodiment of the present invention.

FIG. 13 is a table of outputs, in accordance with one embodiment of thepresent invention.

FIG. 14 is a mouse method, in accordance with one embodiment of thepresent invention.

FIG. 15 is a side elevation view, in cross section, of a mouse, inaccordance with one embodiment of the present invention.

FIG. 16 is a block diagram of a mouse, in accordance with one embodimentof the present invention.

FIG. 17 is a diagram a graphical user interface, in accordance with oneembodiment of the present invention.

FIG. 18 is an input control method, in accordance with one embodiment ofthe present invention.

FIG. 19 is an exploded perspective view of a mouse, in accordance withone embodiment of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

The present invention pertains to a mouse having improved inputmechanisms. One aspect of the invention relates to mice with touchsensing areas capable of generating input signals. The touch sensingareas may for example be used to differentiate between left and rightclicks in a single button mouse. Another aspect of the invention relatesto mice with force sensing areas capable of generating input signals.The force sensing areas may for example be positioned on the sides ofthe mouse so that squeezing the mouse generates input signals. Anotheraspect of the invention relates to mice that include a jog ball. The jogball may be used for positioning a cursor or for providing a way tocontrol scrolling or panning. The jog ball may also be used to providebutton events.

Embodiments of the invention are discussed below with reference to FIGS.2-19. However, those skilled in the art will readily appreciate that thedetailed description given herein with respect to these figures is forexplanatory purposes as the invention extends beyond these limitedembodiments.

FIG. 1 is a perspective view of a mouse 20, in accordance with oneembodiment of the present invention. The mouse 20 is a movable handheldinput device for providing user commands to a host system such as acomputer. In most cases, the mouse 20 is configured to control movementssuch as a cursor and initiate commands via one or more clicking actions.The mouse 20 may be coupled to the host system via a wired or wirelessconnection. In the case of wired connections, the mouse 20 may include acable for connecting to the host system. In the case of wirelessconnections, the mouse may include a radio frequency (RF) link, opticalinfrared (IR) link, Bluetooth link or the like in order to eliminate thecable.

The mouse 20 generally includes a housing 22 that provides a structurefor moving the mouse 20 along a surface and for gripping the mouse 20for movement thereof. The housing 22 also helps to define the shape orform of the mouse 20. That is, the contour of the housing 22 embodiesthe outward physical appearance of the mouse 20. The contour may berectilinear, curvilinear or both. In most cases, a bottom member 24 ofthe housing has an external contour that substantially conforms to thecontour of a flat surface such as a desktop. In addition, a top member26 of the mouse housing 22 generally has an external contour thatsubstantially conforms to the contour of the inside surface of a hand.

The housing 22 also provides a structure for enclosing, containingand/or supporting the components of the mouse 20. Although not shown,the components may correspond to electrical and/or mechanical componentsfor operating the mouse 20. For example, the components may include aposition detection mechanism such as a track ball or optical assemblythat monitors the movement of the mouse 20 along a surface and thatsends signals corresponding to the movements to the host system. In mostcases, the signals produced by these components direct an input pointerto move on a display screen in a direction similar to the direction ofthe mouse 20 as it is moved across a surface. For example, when themouse 20 is moved forward or backwards, the input pointer is movedvertically up or down, respectively, on the display screen. In addition,when the mouse 20 is moved from side to side, the input pointer is movedfrom side to side on the display screen.

The mouse 20 may be configured as a conventional mouse or a unibodymouse. If configured as a conventional mouse, the mouse includes one ormore mechanical buttons that move relative to the top member of thehousing 22. If configured as a unibody mouse, the functionality of abutton (or buttons) is incorporated directly into the housing 22 of themouse 20. For example, the top member 26 may pivot relative to thebottom member 24 (as opposed to attaching separate button caps throughthe housing). In either case, during a clicking action, the movablecomponent of the mouse 20 (whether a mechanical button or a top member)is configured to engage a switch located within the housing. Whenengaged, the switch generates a button event signal that can be used toperform an action in the host system.

In the illustrated embodiment, the mouse is a unibody mouse. In thisparticular embodiment, the entire top member 26 is configured to pivotabout an axis 28 located in the back of the mouse 20. The axis 28 may beprovided by a pivot joint that connects the top and bottom members 26and 24. This arrangement allows the front portion of the top member 26to move downward when a force is applied on the front of the top member26 (e.g., the top member swings around the axis 28). When forceddownward, an inner surface of the top member 26 presses against theinternal switch located within the housing 22 thereby generating thebutton event signal.

In order to increase the button functionality of the mouse 20 (whilelimiting breaks or lines in the housing), the mouse 20 may furtherinclude a plurality of button zones 30 on the surface of the housing 22.The button zones 30 represent regions of the housing 22 that may betouched or pressed to implement different button functions (with orwithout a clicking action). By way of example, the button functions mayinclude making selections, opening a file or document, executinginstructions, starting a program, viewing a menu, and/or the like.

The button zones 30 are generally provided by sensors located beneaththe outer surface of the housing 22. The sensors are configured todetect the presence of an object such as a finger when a finger sits on,presses or passes over them. The sensors may also be capable of sensingthe amount of pressure being exerted thereon. The sensors may bedisposed underneath the inner surface of the housing 22 or they may beembedded in the housing 22 itself. By way of example, the sensors may betouch sensors and/or pressure/force sensors.

The position of the button zones 30 may be widely varied. For example,the button zones 30 may be positioned almost anywhere on the mouse 20,including both moving and stationary components of the mouse, so long asthey are accessible to a user during manipulation of the mouse 20 (e.g.,top, left, right, front, back). Furthermore, any number of button zones30 may be used. Moreover, the button zones 30 may be formed from almostany shape and the size may vary according to the specific needs of eachmouse. In most cases, the size and shape of the button zones 30correspond to the size that allows them to be easily manipulated by auser (e.g., the size of a finger tip or larger). The size and shape ofthe button zones 30 generally corresponds to the working area of thesensor.

In accordance with one embodiment of the present invention, at least aportion of the button zones 30 are based on touch sensing. The touchsensing button zones 30A provide inputs when the user touches thesurface of the mouse 20. The input signals can be used to initiatecommands, make selections, or control motion in a display. The touchesare recognized by a touch sensing device located underneath or withinthe housing 22. The touch sensing device monitors touches that occur onthe housing 22 and produces signals indicative thereof. The touchsensing device may for example include one or more touch sensors basedon resistive touch sensing, capacitive touch sensing, optical touchsensing, surface acoustic wave touch sensing, and/or the like.

In one embodiment, each of the touch sensing button zones 30A utilizecapacitance sensors. The capacitance sensors may be in the form ofelectrodes or wires disposed underneath the outer surface of the housing22. As the finger approaches the outer surface of the mouse 20, a tinycapacitance forms between the finger and the electrode/wires in closeproximity to the finger. The capacitance in each electrode/wire ismeasured by a capacitance sensing circuit or by the main microcontrollerof the mouse. By detecting changes in capacitance at each of theelectrode/wires, the microcontroller can determine the presence orabsence of a finger on a particular button zone 30A.

Although the touch sensing button zones 30A may be positioned anywhereon the mouse, in one embodiment, at least two touch button zones 30A arelocated on a physical button of the mouse 20 so as to increase thefunctionality of the physical button. For example, the touch buttonzones 30A may be positioned on a mechanical button in a conventionalmouse or the top member 26 in a unibody mouse (as shown). In eithercase, both the physical buttons as well as the button zones 30A in theregion of the press generate signals. That is, the switch of thephysical button generates a first signal when the physical button ispressed, and the sensors of the button zones 30A in the region of thepress generate additional signals. The signals generated by the switchand sensors may be interpreted in a variety of ways either separately orin combination, and may even be assignable by a user as for exampleusing a preference window or control panel.

In one implementation, the button zones 30A are positioned on the leftand right sides of a single physical button so that a single physicalbutton can operate like conventional left and right mechanical buttons.The left and right button zones 30A help determine whether a singleclicking action is a left or right clicking action. When a user presseson the left side of the single physical button (e.g., top member 26),two signals are generated, one from the switch, the other from the touchsensor located on the left side. These two states may be interpreted asa primary or left click button event. When a user presses on the rightside of the single physical button (e.g., top member 26), two signalsare generated, one from the switch, the other from the touch sensorlocated on the right side. These two states may be interpreted as asecondary or right click button event.

In the case where fingers press on both the right and left sides(simultaneous), three signals are generated, one from the switch, onefrom the touch sensor located on the left side and another from thetouch sensor located on the right side. These three states may beinterpreted in a variety of ways. For example, they may be interpretedas a primary or left button click, a third distinct button event or evenalternating or simultaneous left and right button events. The lastexample may be beneficial in game playing where a user typically has tophysically alternate between left and right clicks to perform an actionin the game.

In one embodiment, a visual preview clue may be provided on-screen whena finger is lightly pressing one or both of the touch sensors. Lightlypressing may for example correspond to the condition when a finger isplaced over the touch sensor, but the press is not hard enough toactivate the main switch. The visual clue alerts a user to which buttonwill be activated when the main switch is finally pressed (hard touch).The visual clue may for example be a menu icon when the secondary (rightbutton) is touched, and an arrow icon when the primary (left button) istouched. Alternatively or additionally, the touch buttons may beilluminable touch buttons that illuminate when the touch button islightly pressed thereby alerting the user as to which button will beactivated.

In accordance with another embodiment of the present invention, at leasta portion of the button zones 30B are based on pressure or forcesensing. The force sensing button zones 30B provide inputs when forcesare applied to the housing 22 of the mouse 20. The input signals can beused to initiate commands, make selections, or control motion in adisplay. In this embodiment, the housing 22 typically provides a slightamount of flex so that any forces exerted thereon can be distributed toa force sensing device located underneath the housing 22. The forcesensing device monitors the forces on the housing 22 and producessignals indicative thereof. The force sensing device may for exampleinclude one or more force sensors such as force sensitive resistors,force sensitive capacitors, load cells, pressure plates, piezoelectrictransducers, strain gauges and/or the like.

The force sensors may be attached to the under surface of the housing 22or to a structural platform located within the housing 22. When a forceis applied to the housing 22 (squeezing or pushing on the housing), theforce is transmitted through the housing 22 to the force sensor locatedunderneath the housing 22. That is, the housing 22 flexes minimally, butstill enough to be sensed by the force sensor sandwiched between thehousing 22 and the internal structural platform.

In one particular implementation, the force sensing button zones 30B arelocated on opposing sides of the housing 22 on the top member 26 or thebottom member 24. The sides of the housing 22 are ideal places forimplementing a squeeze gesture. This is because the users fingers aretypically positioned on one side of the mouse 20 and thumb on the otherside of the mouse 20 and therefore the hand may easily squeeze the sidesvia a pinching action. The squeeze gesture can be used alone orsimultaneously with button clicks and pointing. For example, the squeezegesture can be used to initiate control functions such as zoom, pan,resize, volume control, and the like where the squeeze is a physicalmetaphor for the action itself.

The squeeze gesture may also be used in combination with traditionalbutton clicks or pointing to modify the button clicks or pointing or togenerate other control functions. For example, the squeeze gesture canbe used with standard GUI functions in a way where increased pressuretranslates to a more intense level of the standard GUI function (e.g., acharacteristic of the standard GUI function is based on the amount ofpressure). By way of example, the speed of a standard GUI function maybe related to the pressure being exerted on the sides of the mouse(e.g., faster scrolling with increased pressure and slower scrollingwith decreased pressure).

Because it is so convenient to activate the squeeze gesture, specialcare must be taken when designing the squeeze feature so that it willnot be accidentally activate during normal use, i.e., needs to be ableto differentiate between light and hard squeezes. By way of example, thesqueeze feature may be implemented using force sensitive sensors such asa force sensitive resistor (FSR) or capacitor (FSC). FSR's, exhibit adecrease in resistance with an increase in force applied to its activesurface while FSC's exhibit an increase in capacitance with an increasein force applied to its active surface. A comparator circuit can be usedto output a high signal to indicate activation when a preset forcethreshold is reached.

In one implementation, the squeeze gesture (pressing the sides of themouse) is configured to control one or more features of a windowmanagement program such as Expose' manufactured by Apple Computer Inc.of Cupertino, Calif. Window management programs are configured to helpnavigate through or mitigate window clutter (the state where its isdifficult to find documents or see the desktop because there are so manyopen windows and/or applications).

Expose' in particular has three different modes of operation, which canbe controlled by the squeeze gesture. The first mode is All Windows orTile, Scale and Show all. When operating in this mode, all open windowsare tiled and scaled so that all the open windows can be seensimultaneously inside the display screen. That is, squeezing the sidesof the mouse 20 instantly tiles all of the open windows—scales them downand neatly arranges them so that the user can view the contents in eachwindow. The amount of scaling or the rate of scaling may be tied to theamount of pressure be exerted on the sides of the mouse 20. The secondmode is Application Windows or Highlight Current Application. This modeworks similarly to the first mode except that it only works on aparticular application. For example, squeezing the sides of the mouse 20may instantly tile the open windows of a particular application whilecausing all of the other open application to fade to a shade of grey.The third mode is Desktop or Hide All. In this mode, all of the openwindows are moved to the screen edges thereby opening up the desktop.That is, squeezing the sides of the mouse 20 may hide all of the openwindows giving the user instant access to their desktop.

In accordance with another embodiment of the present invention, themouse 20 includes a jog ball 32. The jog ball 32 is configured toreplace the conventional scroll wheel. Unlike the scroll wheel, the jogball 32 is capable of rotating or spinning in multiple directions andtherefore generating multidirectional signals similar to a track ball.Unlike a track ball, however, the jog ball 32 includes a much smallerball that is sealed inside a housing. The smaller ball makes it easy toperform operations using one finger, and because the ball is sealedinside a housing this technique is less prone to dirt and dust (e.g.,the ball does not have to be removed and cleaned). Furthermore, insteadof using mechanical encoders as in track balls, the jog ball 32 utilizesa non contact magnetic configured ball and a hall IC. As the ball spinsaround, the hall IC detects the magnetic field of the spinning ball, andgenerates signals indicative thereof. In some cases, the jog ball 32 mayeven include a spring actuated switch that activates when the ball ispressed down. This may operate as a third button of the mouse.

The ball is preferably sized smaller than 10 mm, more particularlybetween about 5 and about 8 mm and even more preferably about 7.1 mm.The smaller ball is easily actuated by a single finger (unlike largertrackballs which are unwieldy for one finger), saves real estate of themouse for the button zones (unlike large trackballs which take up mostof the usable surface area), is more aesthetically pleasing (not asobtrusive as a track ball), and does not take up a large amount of spaceinside the mouse housing (unlike trackballs).

By way of example, the jog ball 32 may correspond to the WJN series jogball switch manufactured by Panasonic Corporation of North America. TheEVQWJN series jog ball in particular includes a switch and has overalldimensions of 10.7 mm×9.3 mm×6 mm with a 5.5 mm ball.

The placement of the jog ball 32 may be widely varied. In most cases,the placement is such that it can be easily manipulated by a finger whenthe hand is holding the mouse 20. In one particular embodiment, the jogball 32 is positioned in front center of the mouse 20. For example, thejog ball 32 may be fixed to the housing 22 of the mouse 20 andpositioned between the left and right mechanical buttons in aconventional mouse or fixed to the movable top member 26 between theleft and right touch button zones 30A in a unibody mouse. Alternatively,the jog ball 32 may be positioned on the sides of the mouse 20.

In one embodiment, the jog ball 32 includes a switch. The jog ballswitch is used in combination with the main switch of the unibody mouse20 to implement a third button. For example, if the switch of the jogball 32 and the main switch are activated together, a third buttonsignal is generated. If one is activated and the other is deactivated,the third button signal is not generated. Generally speaking, in orderto cause the third button to activate, the user has to provide enoughforce to press the jog ball 32 down as well as the top member 26 so thatthe top member 26 engages the main switch located inside the mouse 20.

In one embodiment, the jog ball 32, which spins freely inside a housingin all directions, is configured to provide a scrolling or panningfunction for the mouse 20 so that a user can move the GUI vertically (upand down), and horizontally (left and right) in order to bring more datainto view on a display screen. For example, the jog ball 32 may bearranged to move the GUI vertically up when spun towards the front ofthe mouse 20, vertically down when spun towards the back of the mouse20, horizontally to a right side when spun towards the right side of themouse 20, and horizontally to a left side when spun towards the leftside of the mouse 20.

In another embodiment, at least some of the signals generated by the jogball 32 are used for scrolling/panning while the remaining signals areused for button events. For example, vertical scrolling may beimplemented when the jog ball 32 is spun up and down, and a right buttonevent or fourth button may be implemented when the jog ball is spun tothe right, and a left button event or fifth button may be implementedwhen the jog ball is spun to the left. That is, the horizontalscroll/panning is disabled in order to enable additional buttonfunctionality while maintaining the vertical scroll/pan functionality.

In accordance with another embodiment of the present invention, becausethe input means (button zones and jog ball) may not provide soundfeedback when activated (e.g., no mechanical detents), the mouse mayfurther include an on-board speaker that provides an audible clickingnoise when at least some of these devices are activated. The audibleclicking noise may be distinct to each input mechanism, or the sameclicking noise may be used. As should be appreciated the sound feedbackenhances the usability of the mouse as the user is able to positivelyconfirm that his action has resulted in an actual activation of theinput mechanism. During operation, the microcontroller of the mousesends a driving signal to the speaker when the appropriate input isreceived from the input mechanisms, and the speaker outputs one or more“clicks” in response to the driving signal.

Referring to FIGS. 2 and 3, one embodiment of a unibody mouse 100 willbe described in greater detail. The unibody mouse 100 may for examplecorrespond to the mouse shown and described in FIG. 1.

As shown in FIG. 2, the unibody mouse 100 includes a plastic top shell102 that pivots relative to a plastic base 104. The pivot point 106 istypically located at the back of the mouse 100. This allows the frontportion of the top shell 102 to move downward towards the base 104 whena force is applied on the front of the top shell 102 (e.g., the topshell swings around the pivot point). When the plastic top shell 102 isforced down at the front, it activates a main switch 108 that causes amicrocontroller in the mouse 100 to send a button down event to a hostcomputer. One embodiment of a unibody mouse such as this can be found inU.S. Pat. No. 6,373,470, which is herein incorporated by reference.

In order to provide additional inputs, the mouse 100 also includescapacitive sensors 112 that are placed at suitable locations across thetop shell 102. The capacitive sensors 112 are configured to detect whereportions of the hand, and more particularly one or more fingers, arecontacting the surface of the mouse 100. Because the capacitive sensors112 can detect fingers through a plastic surface of a severalmillimeters thick, the capacitive sensors 112 can be either embedded inthe plastic top shell 102 or fixed to the underside of the plastic topshell 102 (as shown).

The capacitive sensors 112 may be widely varied. In one embodiment, thesensors 112 are in the form of conductive electrodes 113 that areoperatively coupled to a capacitive sensing circuit that monitors thecapacitance at each electrode 113. The capacitance sensing circuit mayfor example be a separate or integral component of the microcontrollerof the mouse 100. The conductive electrodes 113 may be any thin metallicmaterial. By way of example, the electrodes 113 may be embodied as ametallic foil such as copper foil tape that is adhered to the innersurface of the top shell 102, a conductive paint or ink that is coatedon the inner surface of the top shell 102 (e.g., PET with silver ink), aflexible printed circuit (FPC) with copper print that is glued or tapedto the inner surface of the top shell 102, a wire or band that is moldedinto the top shell 102, and/or the like.

The size, shape and position of the conductive electrodes 113 can bemodified to increase the sensitivity of the electrodes 113. As a generalguide, the static capacitance of the electrodes 113 (without the fingertouching it) should be kept as small as possible. Furthermore, when afinger is touching the electrodes 113, the change in capacitance shouldbe made as large as possible (the ratio of the capacitance between thetwo states should be maximized). In one implementation, the electrodeconfiguration is configured to produce an increase of 3-5% in theelectrode capacitance when a finger is touching the electrode. Somefactors that affect the capacitance include but are not limited by: areaof the electrodes, distance between electrodes and the thickness of thetop shell. Each of these factors can be varied separately or incombination with each other to achieve the desired results. That is, itmay be necessary to test different combinations of these parameters toreach an optimal design for a particular application.

In one embodiment, the surface area of the electrodes is reduced byremoving sections from the electrodes 113. For example, the electrodes113 may be configured with various holes or voids 114 that are randomlyor symmetrically placed in the electrodes 113 (e.g., Swiss cheese).Alternatively, the electrodes 113 may be formed from rows and columns ofwoven or attached wires with spaces between the rows and columns (e.g.,chain link or mesh).

Additionally or alternatively, the thickness of the electrode 113 may bereduced in order to increase the sensitivity of the electrodes 113. Thethickness may for example be between about 0.2 and about 0.4 mm thickwhen using copper foil.

As shown in FIG. 3, which illustrates the underbelly of the top shell102, the mouse 100 includes two capacitance sensing electrodes 113 thatare spatially separated and positioned on opposite sides of the mouse100. A first electrode 113A is placed on the front left side of the topshell 102 and a second electrode 113B is placed on a front right side ofthe top shell 102. That is, the first electrode 113A is placed to theleft of the centerline 116 of the mouse 100, and the second electrode113B is placed to the right of the centerline 116 of the mouse 100.

By placing the electrodes 113 at the front of the mouse in the left andright positions, the unibody mouse 100 can be operated like aconventional two button mouse. The signals generated by the main switchand left sensor 112A indicate a primary button event, and the signalsgenerated by the main switch and the right sensor 112B indicate asecondary button event. To activate the primary button (left click), theuser places their finger on the left side of the top shell 102 over theleft electrode 113A and applies a force on the top shell 102 until thetop shell 102 activates the main switch 108. Likewise, to activate thesecondary button (right click), the user places their finger on theright side of the top shell 102 over the right electrode 11 3B, andactivates the main switch 108 by applying a force on the top shell 102.One advantage of this configuration is that the force needed to activatethe left and right buttons are the same.

As should be appreciated, the button detection algorithm requires twosignals to be detected to determine whether the primary or secondarybutton is activated. For primary button detection, the left sensor 112Aand main switch are activated. For secondary button detection, the rightsensor 112B and main switch are activated. In cases where the left andright sensors as well as the main switch are activated, severaldifferent functions may be performed. In some cases, the user may wantto activate the primary and secondary buttons at the same time (whenplaying a game that requires them to be used in this manner). In othercases, the user may want the mouse to interpret the two sensors and themain activation (at the same time) as primary button activation. In yetother cases, the user may want the mouse to interpret the two sensorsand the main switch activation (at the same time) as a third button.

Alternatively, the position of the primary and secondary buttons can bereconfigured via software as necessary to suit a left or right handedperson, i.e., a right handed person typically prefers the primary buttonto be on the left and a left handed person typically prefers the primarybutton on the right.

Alternatively or additionally, the sensors may operate independentlyfrom the switch. For example, the mouse may be configured with inputsthat are created when the touch sensors are lightly touched so that theswitch is not activated. A light touch on the left touch sensor maygenerate a second left button event, and a light touch on the righttouch sensor may generate a second right button event. In a manner ofspeaking, the switch may be used to differentiate between light and hardtouches.

A control panel may be provided in the host system to let a user choosehow the sensors/switches are to be interpreted.

In most cases, the capacitive sensing method mentioned above relies on achange in capacitance at the electrodes caused by the introduction of afinger on the sensor. The human body is essentially a capacitor and addsto the electrode capacitance when the finger touches it with the returnpath being the ground (floor) the person is standing on or any part ofthe body that touches a ground. Because there are instances where aperson may not have a ground path back to the mouse/computer system,e.g. sitting with legs folded on a plastic chair, the capacitance sensordesign may be configured with a pair of capacitive electrodes on eachside of the mouse in the touch area, e.g., front of mouse. With at leasttwo electrodes per side, the “floating finger” provides a capacitivecoupling between them thus causing a change in capacitance. That is, thefloating finger forms a coupling between the two electrodes, and thiswill add to the capacitance of the electrodes, which then can beinterpreted as a finger is present.

FIG. 4 is a mouse method 200, in accordance with one embodiment of thepresent invention. The mouse method may be performed on the mousedescribed in FIGS. 2 and 3. The mouse method 200 begins at block 202where a determination is made as to whether or not the left sensor isactivated. If the left sensor is activated, the method proceeds to block204 where a determination is made as to whether or not the main switchis activated. If the main switch is activated, the method proceeds toblock 206 where a left button event is reported.

If the left sensor or main switch is not activated, the method proceedsto block 208 where a determination is made as to whether or not theright sensor is activated. If the right sensor is activated, the methodproceeds to block 210 where a determination is made as to whether or notthe main switch is activated. If the main switch is activated, themethod proceeds to block 212 where a right button event is reported.

If the right sensor or main switch is not activated, the method proceedto block 214 where a determination is made as to whether or not theright and left sensors are simultaneously activated. If the sensors aresimultaneously activated. The method proceeds to block 216 where adetermination is made as to whether or not the main switch is activated.If the main switch is activated, the method proceeds to block 218 whichhas several possible outcomes depending on the user's needs. Theoutcomes may be selectable by the user via a control panel.

In one embodiment, block 218 includes only reporting only a left orright button event. In another embodiment, block 218 includes reportingboth left and right button events (simultaneously or alternating). Inyet another embodiment, block 218 may include reporting a third buttonevent. If the right and left sensor or main switch is not activated, themethod proceeds back to the beginning and starts over.

FIG. 5 is a mouse method 230, in accordance with one embodiment of thepresent invention. This method is similar to the method of FIG. 4, withthe exception that if a determination is made that there is no click,additional button events are reported based on only the various touches.For example, if the left sensor is activated, and the right sensor andmain switch are not activated, the method proceeds to block 232 where afirst light touch button event is reported. If the right sensor isactivated, and the left and sensor and main switch are not activated,the method proceeds to block 234 where a second light touch button eventis reported. If the left sensor and the right sensor are activated andthe main switch is not, the method proceeds to block 236 where a thirdlight touch button event is reported.

FIG. 6 is an example of a the mouse vocabulary table 240 based onmethods described in FIGS. 4 and 5. As shown, the table 240 includes thesignals produced by the main switch, left sensor and right sensor aswell as what is reported when the various signals are activated ordeactivated.

Referring to FIGS. 7 and 8, one embodiment of a unibody mouse 300 willbe described in greater detail. The unibody mouse 300 may for examplecorrespond to the mouse shown and described in FIG. 1. Similar to theunibody mouse mentioned in FIGS. 2 and 3, the unibody mouse of FIGS. 7and 8 includes a housing 302 having a top member 304 that pivotsrelative to a base 306 in order to activate an internal switch (notshown).

The housing 302 additionally includes wings 308 positioned at both sidesof the mouse 300. The wings 308 are an extension of the base 306 and areseparate from the top member 304. The wings 308, which extend above thebase 306 and into the sides of the top member 304, are typically flushwith the outer surface of the top member 304. Although in some instancesthe wings 308 may be recessed or protrude away from the outer surface ofthe top member 304. The wings 308 allow a user to hold the mouse 300with their finger and thumb so that the mouse 300 can be moved about asurface without tilting the top member 304. The wings 308 also allow theuser to hold the internal switch closed (top member down) while liftingand moving the mouse 300. This operation is commonly used in situationswhere the user needs to move the cursor across the display screen andhas very little workspace to move the mouse 300. This is sometimesreferred to as a “lift and drag” operation.

Because the fingers and thumb are usually at the wings 308 or in closeproximity to the wings 308 when the mouse 300 is being held, the wings308 are ideal locations for implementing one or more input features. Theuser can press one or both of the wings 308 in order to generate variousinputs. In fact, the wing buttons can work similarly to the touchbuttons mentioned above. In one embodiment, each of the wings produces aseparate input when pressed. In another embodiment, pressing on one orboth of the wings produces the same control signal. The laterarrangement can accommodate almost any hand position includingconventionally at the sides of the mouse or unconventionally such astransverse to the conventional position or on only one side of themouse.

In one embodiment, the input features are implemented with force sensors310, and more particularly force sensitive resistors or capacitors, thatare positioned behind the wings 308 and that produce data that variesaccording to the pressure exerted on the wings 308 when the wings 308are pressed. The data (e.g., changes in resistance, capacitance, etc.)may be used to produce binary control inputs such as on/off oractivate/deactivate via control circuitry. This may be accomplished whena predetermined force threshold is reached. Alternatively, the data maybe used to produce variable control inputs that vary according to theforce being applied. In either case, the mouse 300 typically includes amicrocontroller 312 that monitors the output of the force sensors 310and generates signals indicative thereof.

As shown in FIG. 8, the wings 308 extend above the surface of the base306 and therefore they act like flexures that are capable of bendinginwardly when a force is applied thereto (slight amount of flex).Furthermore, the sensors 310 are positioned between the inner surface ofthe wings 308 and a bridge 314 located within the housing 302. Thebridge 314 may for example be a rigid piece of plastic that is attacheddirectly or indirectly to the base 306. The sensors 310 may floatbetween the bridge 314 and wings 308 or the sensors 310 may be attachedto either the wings 308 or the bridge 314 (as shown).

When a force is applied to the wings 308 as for example by the pinchingnature of the hand, the wings 308 flex inwardly and press against thesensors 310, which abut a flat surface of the bridge 314. The FSRsexhibit a decreased resistance with increasing levels of force while theFSCs exhibit an increased capacitance with increasing levels of force.The data generated therefrom may be used to produce control inputs basedon the force applied at the wings 308.

When the input feature is operated as a binary input device, themicrocontroller 312 is configured to produce binary inputs such ason/off based on a particular resistance of the FSRs or a particularcapacitance of the FSCs. In the case of FSRs, if the resistance fallsbelow a certain level, then the microcontroller 312 may treat thesqueeze as a button event. In the case of FSCs, if the capacitance risesabove a certain level, then the microcontroller 312 may treat thesqueeze as a button event. In some cases, a comparator circuit may beused to output a high signal that indicates button activation when apreset force threshold is reached. In fact, the mouse 300 may includetwo activation force thresholds, one for normal operations and one forlift and drag operations.

When the input feature is operated as a variable input device, themicrocontroller 312 is configured to produce variable inputs that varyaccording to the resistance of the FSRs or the capacitance of the FSCs.

In one particular embodiment, the force sensors 310 correspond to FSCs.FSCs tend to be more cost effective than FSRs, and in cases where themouse includes both the squeeze feature and the capacitive touch sensorspreviously described (FIGS. 2 and 3), the same capacitance sensingcircuit can be used to monitor the capacitance at the capacitance touchsensors and the capacitance force sensors.

In one implementation, the FSCs consist of parallel conductive platesseparated by one or more deformable spacers. When the sensor is pressed,the distance between the plates becomes smaller thereby increasing thecapacitance, which is read by the capacitance sensing circuit andthereafter reported to the microcontroller of the mouse.

As shown in FIG. 9, the inner surface of the wings 308 may include aplunger or nub 320 that presses against the sensors 310 when the wings308 are forced inwardly rather than having a flat surface as shown inFIG. 8. The plunger 320, which protrudes from the inner surface, helpstransmit the force from the wings 308 to the sensors 310 therebyenhancing the operation of the sensors 310. Alternatively, the plunger320 may be placed on the flat surface of the bridge 314.

Although not shown, in some cases, in order to ensure that the inputfeatures work properly when squeezed, a shim may be needed to fill gapsor spaces found between the sensors 310 and the wings 308 or between thesensors 310 and the bridge 314.

FIG. 10 is a mouse method 400, in accordance with one embodiment of thepresent invention. The mouse method 400 generally begins at block 402where the force at the sides of the mouse are monitored. This may beaccomplished using the arrangement shown in FIGS. 7 and 8.

Following block 402, the method proceeds to block 404 where adetermination is made as to whether or not the mouse has been lifted offthe table (e.g., lift and drag operation). This may be accomplished bypolling the surface quality (SQUAL) value from the optical trackingsensor of the mouse. The optical tracking sensor uses an opticalnavigation technology that measures changes in position by opticallyacquiring sequential surface images and mathematically determining thedirection and magnitude of the changes. The sensor provides a SQUALvalue that is a measure of the number features on the surface that isvisible to the sensor. When the mouse is on a work surface, the sensorsees features of the work surface and thus it returns a non-zero for theSQUAL value. When the mouse is lifted off the table, the sensor does notsee any features on the work surface and thus it returns a zero for theSQUAL value.

If the mouse has not been lifted off the table, the method 400 proceedsto block 406 where a determination is made as to whether or not a firstforce threshold has been exceeded. The first force threshold is set at aforce level that is higher than the force typically required to hold thesides of the mouse during normal use. As should be appreciated, the useforce is typically very low compared to a force associated with asqueeze. If the first force threshold is exceeded, the method proceedsto block 408 where a button event is generated. If the first forcethreshold is not exceeded, the method proceeds back to block 402.

Referring back to block 404, if it is determined that the mouse has beenlifted off the table, then the method proceeds to block 410 where adetermination is made as to whether or not a second force threshold hasbeen exceeded. The second force threshold is set at a force level thatis higher than the force required to hold the mouse during a liftingoperation. As should be appreciated, the lifting force is typically muchhigher than the first force described above. If the second forcethreshold has been exceeded, the method proceeds to block 412 where abutton event is generated. If the second force threshold is notexceeded, the method proceeds back to block 402.

Using the implementation of the optical tracking sensor, when the forceexerted on the sides of the mouse is greater than the first force andthe SQUAL value is non zero, this is an indication that the user isperforming a squeeze gesture at the sides of the mouse during normal useand that a button event should be generated. When the force exerted onthe wings is greater than the second force and the SQUAL value is zero,this is an indication that the user is performing a squeeze gesture atthe sides of the mouse during a lift and drag operation and that abutton event should be generated.

FIG. 11 is a resistance verses force diagram 420 of an FSR, inaccordance with one embodiment of the present invention. Several forcethresholds are shown. F1 is the force at the sides of the mouse duringnormal usage. F2, which is greater than F1, is the force required toactivate the squeeze button when the mouse is on a work surface. F3,which is greater than F2, is the force at the sides of the mouse whenperforming a lift and drag operation. F4, which is greater than F3, isthe force required to activate the squeeze button during the lift anddrag operation.

FIG. 12 is diagram of a comparator circuit 430, in accordance with oneembodiment of the present invention. The comparator circuit 430 isconfigured to output a “high” signal when the low force F2 and the highforce F4 thresholds are reached. The comparator circuit 430 includes twocomparators U1 and U2 (432 and 434), each of which are connected to anFSR 436. The triggering voltages of the comparators 432 and 434 are setat voltages that correspond to low force threshold U1 and high forcethreshold U2. When the force threshold is reached, the comparatorcircuit 430 outputs a “high” signal. This signal is fed to amicrocontroller that also monitors SQUAL signals from an opticaltracking sensor. When the appropriate signals are received, themicrocontroller outputs a button event signal to the host system. Insome cases, the triggering voltages at U1 and U2 can be made adjustablethrough the use of a digital to analog converter DAC in themicrocontroller. As a result, the user and/or the host system can adjustthe force thresholds to better fit the user.

FIG. 13 is a truth table 440 for determining button activation, inaccordance with one embodiment of the present invention. As shown, thetable includes off table detect signals, high force F4 signals, lowforce F2 signals and the button activation.

FIG. 14 is a GUI operational method 500, in accordance with oneembodiment of the present invention. The method begins at block 502where the pressure at the mouse surface is monitored. This may forexample be performed by the force sensing buttons described above. Inone particular embodiment, the pressure is monitored at one side of themouse, and more particularly at both sides of the mouse. The increasedpressure at the sides may be due to a squeeze gesture being performed. Asqueeze gesture may for example may be defined as a pinching action thatis performed on the mouse between at least two fingers.

Following block 502, the method 500 proceeds to block 504 where adetermination is made as to whether or not a squeeze gesture has beenimplemented at the surface of the mouse. For example, whether or not apredetermined force threshold has been reached.

Following block 504, the method proceeds to block 506 where an action isperformed in a window management program (or other program) based on thepressure at the mouse surface. The action may be widely varied. In oneimplementation, the action includes tiling and scaling down all the openwindows so that all the open windows can be seen simultaneously insidethe display screen. In another implementation, the action includestiling and scaling down all the open windows associated with aparticular application while removing the remaining windows from theforeground (e.g., gray them out). In yet another implementation, theaction includes moving all the opening windows to the screen edgesthereby giving the user instant access to their desktop.

The manner in which the action takes place may be based on the monitoredpressure. In some cases, the rate of scaling is based on the pressureexerted at the surface of the mouse. For example, the rate of scalingmay be increased with increased pressure (or vice versa). In othercases, the size of the tiles may be based on the pressure exerted at thesurface of the mouse. For example, increased pressure may cause smallertiles to be generated (or vice versa).

Referring to FIG. 15, one embodiment of a unibody mouse 550 will bedescribed in greater detail. The unibody mouse 550 may for examplecorrespond to the mouse shown and described in FIG. 1. Similar to theunibody mouse mentioned in FIGS. 2 and 3, the unibody mouse of FIG. 15includes a housing 552 having a top member 554 that pivots relative to abase 556 in order to activate an internal switch (not shown). As shownin FIG. 15, a jog ball 560 is situated in a sealed housing 562 and thesealed housing 562 is mounted on the inside surface of the top member554. The top member 554 includes an opening or hole 564 for receivingthe jog ball 560 which extends out of the sealed housing 562, and whichextends above the top surface of the top member 554 so that it can beeasily spun by a user when the user is holding the mouse. Because thejog ball 560 is smaller than a finger tip, the jog ball 560 is easy tomaneuver with a single finger, and without repositioning the hand. Inaddition, the jog ball including the sealed housing does not take up alot of space inside the mouse 550.

FIG. 16 block diagram of a computing system 450, in accordance with oneembodiment of the present invention. The system 450 includes a mouse 452and a computer 454 such as a desktop computer, lap top computer, handheld computer, and the like. By way of example, the computer 454 maycorrespond to any Apple or PC based computer. The computer 454 generallyincludes a processor 456 configured to execute instructions and to carryout operations associated with the computer system 450. For example,using instructions retrieved for example from memory, the processor 456may control the reception and manipulation of input and output databetween components of the computing system 450. The processor 456 can bea single-chip processor or can be implemented with multiple components.

In most cases, the processor 456 together with an operating systemoperates to execute computer code and produce and use data. The computercode and data may reside within a program storage 458 block that isoperatively coupled to the processor 456. Program storage block 458generally provides a place to hold data that is being used by thecomputer system 450. By way of example, the program storage block 458may include Read-Only Memory (ROM), Random-Access Memory (RAM), harddisk drive and/or the like. The computer code and data could also resideon a removable program medium and loaded or installed onto the computersystem when needed. Removable program mediums include, for example,CD-ROM, PC-CARD, floppy disk, magnetic tape, and a network component.

The computer 454 also includes an input/output (I/O) controller 460 thatis operatively coupled to the processor 456. The (I/O) controller 160may be integrated with the processor 456 or it may be a separatecomponent as shown. The I/O controller 460 is generally configured tocontrol interactions with one or more I/O devices (e.g., mouse 452) thatcan be coupled to the computer 454. The I/O controller 460 generallyoperates by exchanging data between the computer 454 and the I/O devicesthat desire to communicate with the computer 454. The I/O devices andthe computer 454 typically communicate through a data link 462. The datalink 462 may be a one way link or two way link. In some cases, the I/Odevices may be connected to the I/O controller 160 through wiredconnections. In other cases, the I/O devices may be connected to the I/Ocontroller 160 through wireless connections. By way of example, the datalink 162 may correspond to PS/2, USB, IR, RF, Bluetooth or the like.

The computer 454 also includes a display controller 464 that isoperatively coupled to the processor 456. The display controller 464 maybe integrated with the processor 456 or it may be a separate componentas shown. The display controller 464 is configured to process displaycommands to produce text and graphics on a display device 466. Thedisplay device 466 may be integral with the computer or it may be aseparate component of the computer 454. By way of example, the displaydevice may be a monochrome display, color graphics adapter (CGA)display, enhanced graphics adapter (EGA) display,variable-graphics-array (VGA) display, super VGA display, liquid crystaldisplay (e.g., active matrix, passive matrix and the like), cathode raytube (CRT), plasma displays and the like.

The mouse 452, on the other hand, generally includes a microcontroller474 configured to acquire data from the various input mechanisms and tosupply the acquired data to the processor 456 of the computer 454. Inone embodiment, the microcontroller 474 is configured to send raw datato the processor 456 so that the processor 456 processes the raw data.For example, the processor 456 receives data from the microcontroller474 and then determines how the data is to be used within the computersystem 452. In another embodiment, the microcontroller 474 is configuredto process the raw data itself. That is, the microcontroller 474 readsthe pulses from the input mechanisms and turns them into data that thecomputer 454 can understand. By way of example, the microcontroller 474may place the data in a HID format (Human Interface Device).

The microcontroller 474 may be embodied as one or more applicationspecific integrated circuit (ASIC) that are configured to monitor thesignals from the input mechanism, to process the monitored signals andto report this information to the processor (e.g., x, y, button, left,right, etc.). By way of example, this may be implemented throughFirmware.

The mouse 452 also includes a position sensing device 470 which isoperatively coupled to the microcontroller 474. The position sensingdevice 470 is configured to generate tracking signals when the mouse 452is moved along a surface. The tracking signals may be used to controlthe movement of a pointer or cursor on the display screen 466. Thetracking signals may be associated with a Cartesian coordinate system (xand y) or a Polar coordinate system (r, θ). By way of example, theposition sensing device 170 may correspond to a conventional trackballor optical assembly.

The mouse 452 also includes a main switch 476 that is operativelycoupled to the microcontroller 474. The main switch 476 is configured togenerate a button event when the mouse performs a clicking action, asfor example, when the top shell is moved relative to the base in aunibody design.

The mouse 452 may further include a touch sensing device 478 that isoperatively coupled to the microcontroller 474. The touch sensing device478 is configured to generate touch signals when the hand is positionedover or on the mouse 452. The signals may be used to differentiatebetween left and right clicking actions. The touch sensing device mayfor example be arranged similarly to that described above.

The mouse 452 may additionally include a force sensing device 480 thatis operatively coupled to the microcontroller 474. The force sensingdevice 480 is configured to generate force signals when the hand exertspressure on the mouse 452. The signals may be used to initiate a buttonevent. The force sensing device may for example be arranged similarly tothat described above.

Moreover, the mouse 452 may include a jog ball 482 that is operativelycoupled to the microcontroller 474. The jog ball 482 is configured togenerate multidirectional tracking signals when the ball is rotatedwithin a housing. The jog ball 482 may also be configured to generate abutton event when the ball is pressed. The jog ball may for example bearranged similarly to that described above.

Because the touch sensing devices 478, force sensing devices 480 and jogball 482 may not provide any feedback when activated (e.g., nomechanical detents), the mouse 452 may further include a feedback system484 configured to provide feedback to the user of the mouse 452 so thatthe user is able to positively confirm that his action has resulted inan actual activation of an input mechanism as for example one or more ofthe input mechanisms described above (e.g., touch sensing device 478,force sensing device 480, jog ball 482, etc.). The feedback system 484,which is operatively coupled to the microcontroller 474, includes one ormore feedback generators 486 including audio feedback devices 486A,haptics devices 486B and/or visual feedback devices 486C. Each of thevarious feedback generators 486 provides a different kind of feedback tothe user when an input is made. Audio devices 486A provide sound,haptics devices 486B provide tactile forces, and visual devices 486Cprovide visual stimuli. There may be a single feedback generator ormultiple feedback generators that are used by all the input devices whenan action is made, or alternatively, there may be a feedback generatoror multiple feedback generators for each input device. That is, eachinput device may include its own dedicated feedback generators.

In the case of audio feedback generators 486A, the mouse 452 may includeon-board speakers or buzzers such as a piezo electric speaker or a piezoelectric buzzer. These devices are configured to output a clicking noisewhen a user performs an action as for example when a user touches one ofthe touch sensing devices 478, squeezes the presses against the forcesensing devices 480 or spins the jog ball 482. This feature enhances theuser's experience and makes each of these input devices feel more likemechanical input devices.

In one embodiment, the mouse 452 includes a single speaker forgenerating a clicking or other related sound. The single speaker, whichcan be mounted to the main printed circuit board inside the housing ofthe mouse 452, is tied to at least the jog ball 482, and in some casestied to the force sensing device 480. As should be appreciated, thetouch sensing devices 478 typically do not require a click since a clickis already provided by the main switch 476. It should be pointed outhowever that in cases where a light touch also produces an input(without the main switch activating) then a click or other sound may beprovided by the speaker. The speaker may be configured to output thesame clicking sound for each input device, or alternatively the speakermay be configured to output different sounds for each input device. Forexample, clicks, clocks, and beeps may be used. The different sounds maybe user selectable.

During operation, the microcontroller 474 sends driving signals to thespeaker when the appropriate input is received from the input devices,and the speaker outputs one or more sounds in response to the drivingsignals. With buttons, a single click is typically provided although aclick my be provided at touchdown and a clock may be provided on liftoff. In some cases, the feedback may be tied to the level of force beingapplied to the force sensing device 480. For example, the clicking soundmay be provided when a certain force threshold is reached, or the volumeor pitch of the clicking sound may vary according to the level of force.With the jog ball 482, clicks are continuously provided while the ballis spinning. There is typically a click for each count, i.e., the numberof points that are measured in a given rotation (360 degrees). The rateof clicking sounds typically increases as the rate of spinningincreases, and decreases as the rate of spinning decreases or slowsdown. Hence, the clicking sounds provide audio feedback to the user asto the rate at which the ball is spun.

Additionally or alternatively, the mouse 452 may include a hapticsmechanism 486B. Haptics is the science of applying tactile sensation andcontrol to soft devices that do not include any tactile feel. Hapticsessentially allows a user to feel information, i.e., controlledvibrations are sent through the housing of the mouse in response to auser action. The haptics mechanism 486B may include motors, vibrators,electromagnets, all of which are capable of providing force feedback inthe form of controlled vibration or shaking. In the instant case, thehaptics mechanism 486B may be used to enhance the feel of actuating oneof the input devices of the mouse 452 including for example the jog ball482, force sensing device 480 or touch sensing device 478. By way ofexample, the haptics mechanism 486B may be configured to generateimpulsed vibrations when a user touches the touch sensing devices (softor hard), presses against the force sensing devices 480 or spins the jogball 482. This particular feature enhances the user experience and makesthe input devices feel more like mechanical devices.

The haptics mechanism 486B may be centrally located or regionallylocated across the mouse 452. If regionally located, the mouse 452 mayinclude a haptics mechanism 486B at each of the input devices so as toprovide force feedback in the area of the user action. It is generallybelieved that the closer the vibration is to the user action, thegreater the haptics effect. By way of example, the mouse 452 may includea haptics mechanism underneath the housing in the area of each the inputdevices.

In some cases, the audio and tactile feedback may be provided by thesame device. For example, a tactile click generator may be used. Thetactile click generator generally includes a solenoid that causes aplunger to tap a rib inside the mouse housing. The tap provides both atactile feel in the form of vibration and a tapping sound that issimilar to a click.

Additionally or alternatively, the mouse 452 may include visual feedbackgenerators 486C configured to provide visual information at the surfaceof the mouse 452. Like the feedback generators described above, thevisual feedback generators 486C may be singular to the mouse 452 orregionally located at each input device. By way of example, the visualfeedback generators 486C may be light devices, such as light emittingdiodes (LEDs), that are illuminated when an event occurs as for examplewhen a user touches the touch sensing device (soft or hard), pressesagainst the force sensing devices 480 or spins the jog ball 482. Theillumination may be static or dynamic. If dynamic, the illumination mayblink or cycle with increasing or decreasing intensity, and in somecases may even change colors in order to provide more detailedinformation about the event that is being monitored. By way of example,the illumination may be tied to the level of force being applied to theforce sensing devices 480.

The light devices may be conventional indicators that include a smallplastic insert, which is located in front of the LED, and which isinserted within an opening in the mouse housing thus causing it to existat the surface of the mouse housing. The LED itself may also be placedin the opening in the mouse housing rather than using an insert.Alternatively, the light device may be configured not to break thesurface of the mouse housing. In this configuration, the light source isdisposed entirely inside the mouse housing and is configured toilluminate a portion of the mouse housing thereby causing the housing tochange its appearance, i.e., change its color. Examples of illuminatedsurfaces can be found in U.S. Pat. Nos: 10/075,964, 10/773,897 and10/075,520, which are all herein incorporated by reference.Alternatively, the visual feedback generators 486C may be embodied aselectronic inks or other color changing surfaces.

In one embodiment, the mouse 452 provides visual feedback in the area oftouches as for example the left and right touch buttons, and the twoside force buttons when the touches occur. When a user presses on theleft touch button, the left side of the mouse in the region of the touchsurface changes color thereby alerting the user that a left button eventhas been selected, and when a user presses on the right touch button,the right side of the mouse in the region of the touch surface changescolor thereby alerting the user that a right button event has beenselected. The same implementation can be made for the wings of the forcebuttons when the they are pressed in by the user. In some cases, thewings may even change shades of color based on the level of force beingapplied at the wings during a squeeze event.

Each of the feedback generators may be used solely or in combinationwith one other. For example, when used together, in response tosqueezing the force buttons on the side of the mouse, the speaker 486Amay provide audio feedback in the form of a click, the haptics mechanism486B may provide force feedback in the form of vibration, and the visualfeedback mechanism 486C may provide visual stimuli in the form of lightto alert a user that an input has been made. Again, the feedback may beprovided at some central location or regionally at each of the forcebuttons.

Although the feedback systems have been primarily described as devicesthat provide feedback in response to activation of the input devices ofthe mouse, it should be noted that they also may provide feedback inresponse to something that happens in the host system. For example,during a scrolling event, the host system may send a sound command tothe mouse when the user has reached a boundary such as a top or borderof the content being viewed on the display screen. The microcontrollersends a driving signal to the speaker in response to the sound command,and the speaker generates a sound in response to the driving signal. Thesound informs the user that they reached the border.

It should also be pointed out that the feedback may be provided by thehost system rather than the mouse. For example, the host system mayinclude a speaker that provides a click when the mouse buttons areutilized or a display that can visually alert a user when the mousebuttons are being utilized.

In one embodiment, program storage block 458 is configured to store amouse program for controlling information from the mouse 452.Alternatively or additionally, a mouse program or some variation thereofmay be stored in the mouse 452 itself (e.g., Firmware). The mouseprogram may contain tables for interpreting the signals generated in themouse. In one implementation, the tables may be accessed by a userthrough a control menu that serve as a control panel for reviewingand/or customizing the operation of the mouse, i.e., the user mayquickly and conveniently review the settings and make changes thereto.Once changed, the modified settings will be automatically saved andthereby employed to handle future mouse processing. By way of example,the user may set the location of the primary and secondary buttons forright or left handed use. The user may set the meaning of left/rightfinger press to be a primary button, a third button, or a simultaneousleft and right button activation. Additionally, the user may selectbetween a one button mouse and a multibutton mouse. If the single buttonmouse is selected, the signals from the left and right sensors may beignored. If the multibutton mouse is selected, the signals from the leftand right sensors will be interpreted according to the settings in themouse program. One advantage of being able to select the mouse type isthat one mouse can be used by multiple users with different preferences,i.e., user configurable.

FIG. 17 is a diagram a graphical user interface 650 (GUI), in accordancewith one embodiment of the present invention. The GUI 650 represents thevisual display panel for selecting which events of a window managementprogram such as Expose' are controlled by which mouse buttons. Throughthe GUI 650, the user may quickly and conveniently review the mousesettings associated with the window management events and make changesthereto.

As shown, the GUI 650 includes a window frame 652 that defines a windowor field 654 having contents contained therein. The contents include thevarious window management options 656, and mouse menus 658 forconnecting the various mouse buttons to the window management options656. The mouse menus 658 contain all the button possibilities includingthe hard press left and right buttons, the jog ball button, and thesqueeze button. The button menus may also include light press left andright buttons, rotate left and right jog ball buttons and/or left andright squeeze buttons depending on how the mouse is configured. Thebuttons, when enabled, instructs the host system to control the variousexpose functions when the enabled mouse button is activated. Forexample, if the squeeze button is enabled in the Desktop mouse menu,every time the squeeze button is activated the Desktop feature isimplemented, i.e., all the open windows are moved to the screen edge. Insome cases, multiple buttons can be enabled for a single windowmanagement function.

In some cases, the GUI 650 may additionally include a Dashboard option660 and mouse menus 662 for connecting one or more mouse buttons to theDashboard. Dashboard is a control panel that includes customizablewidgets (mini applications) that bring information to the userinstantly—weather forecasts, stock quotes, yellow pages, airlineflights, sport scores, etc. When the enabled mouse button is activated,the Dashboard is brought into view, and when the mouse button isdeactivated, the Dashboard is removed from view. The user is able toreceive up to date and timely info from the Internet with a click of abutton, and then have it disappear instantly when button is released.

FIG. 18 is an input control method 700, in accordance with oneembodiment of the present invention. The input control method may forexample be performed using the arrangements shown in FIGS. 2 and 3 or 7and 8. The method 700 generally begins at block 702 where a touch isdetected. The touch may for example be detected on the left or righttouch sensors or alternatively on both the left and right touch sensorsof the mouse. When a touch is detected, the method 700 proceeds to block704 where a determination is made as to whether or not the touch is alight touch or a hard touch. A light touch may be determined when thetouch sensors are activated but not the main switch. A hard touch may bedetermined when the touch sensors are activated along with the mainswitch.

If it is determined that the touch is a light touch, the method 700proceeds to block 706 where visual feedback is provided that alerts theuser to which button will be activated when the light touch is changedto a hard touch. The visual feedback may be on the mouse and/or on thedisplay screen of the host system. For example, if the user lightlyplaces their finger on the right or secondary button, the right buttonmay change color via a feedback generator and/or the display screen ofthe host system may provide a visual clue in the form of an icon as forexample a menu. In addition, if the user lightly places their finger onthe left or primary button, the left button may change color via afeedback generator and/or the display screen of the host system mayprovide a visual clue in the form of an icon as for example an arrow.

If it is determined that the touch is a hard touch, the method 700proceeds to block 708 where a button action is implemented. For example,if the left button sensor is activated along with the main switch, thena left button event is reported, and if the right button sensor isactivated along with the main switch, then a right button event isreported.

FIG. 19 is an exploded perspective view of a unibody mouse 750, inaccordance with one embodiment of the present invention. The unibodymouse 750 includes a housing 752 that encloses internally the variousinternal components of the mouse. Because the mouse is a unibody mouse,the housing 752 includes a top member 754 and a base 756.

As shown, the base 756 includes a pair of opposed pivots 758 thatreceive pivot pins located within the inside surface of the top member754 thereby allowing the top member 754 to pivot about the base 756. Thebase 756 also includes a pair of opposed flexible wings 760. Althoughthe wings 760 may be integrally connected to the base 756, in theillustrated embodiment, the wings 760 are attached or mounted onto thebase 756. By way of example, the wings 760 may be snapped into mountingfeatures on the base 756. Alternatively, the wings 760 may be welded tothe base 756. In order to produce a continuous surface at the exteriorof the mouse 750 when the mouse is assembled, the top member 754includes a pair of recesses 762 for receiving the upwardly extendingwings 760. The recesses 762 have an inner shape that coincides with theouter shape of the wings 760.

Located within the top member 754 and base 756 is a printed circuitboard 764 that is mounted to the base 756. The printed circuit board 764contains the various control circuitry of the mouse 750 includingintegrated circuits such as the mouse microcontroller and capacitivesensing circuitry. The printed circuit board 764 also contains a switch766 for detecting when the top member 754 is pressed downward towardsthe base 756. The switch 766, which is positioned on the front side ofthe mouse 750 opposite the pivot may for example be a mechanical tactswitch. The printed circuit board 764 and/or the base 756 may alsosupport an optical sensor 768 for tracking mouse movement. The opticalsensor 768 generally works through an opening in the base 756. Theprinted circuit board and/or base may further support a structural unit770 that contains such items as capacitance force sensors 772 that aremounted on the sides of a support bridge 774 in the location of theflexible wings 760. The structural unit 770 may also include a spring775 that helps bias and support the top member 754 in an uprightposition relative to the base 756.

The mouse 750 additionally includes a jog ball device 776 that ismounted to the inner surface of the top member 754 via a bracket 778.The bracket 778 may for example be screwed to the top member 754 so asto secure the jog ball device 776 in position relative to a hole 780 inthe top member 754. The hole 780 allows the ball 782 of the jog balldevice 776 to protrude through the top surface of the top member 754.The hole 780 is typically located in the front center of the top member754 so that the ball 782 may be easily actuated by a finger when thehand is positioned on the mouse 750.

Although not shown, the mouse 750 further includes a pair of capacitivesensors placed on the inner surface of the top member 754 on oppositesides of the jog ball device 776. Each of the capacitive sensors may beone or more electrodes that are adhered to the front inner surface ofthe top member 754.

The mouse 750 may further include a shroud or faring 786 that snaps intothe top member 754 around the edge of the base 756.

While this invention has been described in terms of several preferredembodiments, there are alterations, permutations, and equivalents, whichfall within the scope of this invention. For example, the buttondetermination/detection is not limited to the use of capacitancesensors, other sensors or switches may be used. For example a domeswitch or membrane switch may be used in place of capacitance sensors.In addition, force sensors may be used. In any of these cases, theactivation method remains unchanged, i.e., it requires the new deviceand the main switch to be activated for a button down event to be sentto the host computer. It should also be noted that there are manyalternative ways of implementing the methods and apparatuses of thepresent invention. It is therefore intended that the following appendedclaims be interpreted as including all such alterations, permutations,and equivalents as fall within the true spirit and scope of the presentinvention.

1. A mouse, comprising: a housing; a plurality of button zones on thesurface of the housing, the button zones representing regions of thehousing that are capable of detecting touch events that occur on thesurface of the housing in the region of the button zones.
 2. The mouseas recited in claim 1 wherein at least a portion of the button zones arebased on touch sensing.
 3. The mouse as recited in claim 2 wherein themouse includes a plurality of touch sensors located underneath thesurface of the housing, the working area of the touch sensors formingthe button zones.
 4. The mouse as recited in claim 3 wherein the touchsensors are capacitance touch sensors in the form of electrodes, thecapacitance in each electrode being measured by a capacitance sensingcircuit so as to determine when a touch event is performed on thesurface of the housing in the region of the button zones.
 5. The mouseas recited in claim 1 wherein at least a portion of the button zones arebased on force sensing.
 6. The mouse as recited in claim 5 wherein thehousing provides a minimal amount of flex in the area of the buttonzones so that forces exerted on the button zones are distributed to aforce sensor located underneath the housing in the region of the buttonzones.
 7. The mouse as recited in claim 6 wherein the force sensorscorrespond to force sensitive resistors or force sensitive capacitors.8. The mouse as recited in claim 1 wherein at least a portion of thebutton zones are based on touch sensing and force sensing.
 9. A mouse,comprising: a mouse housing having an outer member; a first touch sensorconfigured to sense the presence of an object at a first region of theouter member; a second touch sensor configured to sense the presence ofan object at a second region of the outer member, the second regionbeing different than the first region; and a sensor management circuitthat monitors the signals output by the first and second touch sensorsand reports button events based at least in part on the signalsgenerated at the first and second touch sensors.
 10. The mouse asrecited in claim 9 wherein the outer member is a physical button capableof performing a clicking action.
 11. The mouse as recited in claim 10wherein the first region is the left side of the physical button, andwherein the second region is the right side of the physical button. 12.The mouse as recited in claim 10 wherein a first button event signal isreported when an object is sensed at the first region but not the secondregion, and wherein a second button event signal is reported when anobject is sensed at the second region but not the first region.
 13. Themouse as recited in claim 10 further comprising: an internal switch thatgenerates an activation signal when the button performs the clickingaction, and wherein the sensor management circuit monitors theactivation signal and reports button events based at least in part onthe signals output by the first and second touch sensors and theactivation signal generated at the internal switch.
 14. The mouse asrecited in claim 13 wherein a first button event signal is reported whenan object is sensed at the first region and the internal switchgenerates an activation signal, and wherein a second button event signalis reported when an object is sensed at the second region and theinternal switch generates an activation signal.
 15. The mouse as recitedin claim 14 wherein, a third button event signal is reported when anobject is sensed at the first region and the internal switch does notgenerate an activation signal, and a fourth button event signal isreported when an object is sensed at the second region and the internalswitch does not generate an activation signal.
 16. The mouse as recitedin claim 14 wherein a third button event is reported when the first andsecond touch sensors simultaneously sense one or more objects.
 17. Themouse as recited in claim 14 wherein the first button event is reportedwhen the first and second touch sensors simultaneously sense one or moreobjects.
 18. The mouse as recited in claim 9 wherein the first andsecond touch sensors are capacitance sensors.
 19. A configurable mousecapable of operating as a single button or multi-button mouse, the mousecomprising: an internal switch that generates an activation signal; asingle moving member that provides a clicking action, the moving memberactivating the internal switch during the clicking action; a touchsensing arrangement that generates a first touch signal when the movablemember is touched in a first region and a second touch signal when themovable member is touched in a second region, wherein the signals of theinternal switch and the touch sensing arrangement indicating one or morebutton events of the mouse.
 20. The configurable mouse as recited inclaim 19 wherein the touch sensing arrangement includes a right touchsensor configured to detect the presence of a touch on the right side ofthe moving member and a left touch sensor configured to detect thepresence of a touch on the left side of the moving member.
 21. Theconfigurable mouse as recited in claim 19 wherein the touch signalsgenerated by the touch sensing arrangement are ignored when the mouseoperates as a single button mouse, and wherein the signals generated bythe touch sensing arrangement are used to determine the meaning of theclicking action when the mouse operates as a multiple button mouse. 22.The configurable mouse as recited in claim 19 wherein the first regionis located on a left side of the moving member, and wherein the secondregion is located on a right side of the moving member.
 23. Theconfigurable mouse as recited in claim 19 wherein a left button event isreported when the first touch signal and the activation signal are theonly signals generated, and wherein a right button event is reportedwhen the second touch signal and the activation signal are the onlysignals reported.
 24. The configurable mouse as recited in claim 19wherein the touch sensing arrangement includes capacitance sensorspositioned within or underneath the moving member.
 25. The configurablemouse as recited in claim 19 wherein the capacitance sensors areembodied as conductive electrodes that are spatially separated andpositioned on opposites sides of the moving member, a first electrodebeing placed in the front left side of the moving member, a secondelectrode being placed in the front right side of the moving member. 26.The configurable mouse as recited in claim 19 wherein the mouse is aunibody mouse, and wherein the moving member is a top member of theunibody mouse.
 27. A mouse, comprising: a housing having one or morepressure sensitive areas; a force sensing device located behind each ofthe pressure sensitive areas, the force sensing devices being configuredto measure the force exerted at the pressure sensitive areas.
 28. Themouse as recited in claim 27 wherein the pressure sensitive areas arelocated on the sides of the housing in an opposed relationship.
 29. Themouse as recited in claim 27 wherein the force sensing devices are forcesensitive resistors or force sensitive capacitors.
 30. The mouse asrecited in claim 27 wherein the mouse is a unibody mouse including a topmember that pivots relative to a base member, the base member includingwings at both sides of the mouse, the wings providing the pressuresensitive areas of the mouse.
 31. The mouse as recited in claim 27wherein the force sensing devices are force sensitive capacitors, theforce sensitive capacitor being located between the wings and a bridgelocated within the mouse.
 32. A mouse, comprising: a jog ball devicepositioned at a surface of the mouse, the jog ball device including aball that spins within a sealed housing, the ball having a diameter thatis less than 10 mm.
 33. The mouse as recited in claim 32 wherein the jogball utilizes a non contact magnetic configured ball and a hallintegrated circuit.
 34. The mouse as recited in claim 32 wherein the jogball device includes a ball switch that generates an activation signalwhen the ball is pushed down inside the sealed housing.
 35. The mouse asrecited in claim 34 further including an internal mouse switch thatgenerates an activation signal when a component of the mouse performs aclicking action, and wherein a button event signal is generated whenboth the ball switch and the internal mouse switch generates anactivation signal.
 36. The mouse as recited in claim 32 wherein a firstbutton event signal is generated when the ball is moved to the left, anda second button event signal is generated when the ball is moved to theright.
 37. The mouse as recited in claim 32 wherein horizontal scrollingperformed when the ball is spun horizontally and wherein verticalscrolling is performed when the ball is spun vertically.
 38. The mouseas recited in claim 32 further including a speaker that provides anaudio clicking noise when the ball is spun.
 39. The mouse as recited inclaim 32 wherein the ball has a diameter between about 5 mm and about 8mm.
 40. A unibody mouse including a base and a movable top member, theunibody mouse comprising: a base including a first wing located on aright side of the mouse, and a second wing located on a left side of themouse; a movable top member coupled to the base; a first touch sensorlocated on a front left side of the top member, the first touch sensorgenerating a first touch signal when the front left side of the topmember is touched; a second touch sensor located on a front right sideof the top member, the second touch sensor generating a second touchsignal when the front right side of the top member is touched; a jogball device located in a front middle portion of the top member betweenthe first and second touch sensors, the jog ball device including a ballconfigured to generate multidirectional motion signals when the ball isspun within a sealed housing, the jog ball device including a switchconfigured to generate a first activation signal when the top member ismoved relative to the base; a first force sensor located behind thefirst wing, the first force sensor generating a force signal whenincreased pressure is exerted on the first wing; a second force sensorlocated behind the second wing, the second force sensor generating aforce signal when increased pressure is exerted on the second wing; aninternal switch configured to generate a second activation signal whenthe top member is moved relative to the base; a position sensing deviceconfigured to generate tracking signals when the mouse is moved along asurface; and a microcontroller that monitors all the signals of theabove mentioned devices and reports tracking and multiple button eventsbased at least in part on these signals solely or in combination withone another.
 41. The unibody mouse as recited in claim 40 wherein thetouch sensors are capacitance touch sensors, and the force sensors areforce sensitive capacitors, and wherein the capacitance of thecapacitance touch sensors and the capacitance of the force sensitivecapacitors are monitored with the same capacitive sensing circuit. 42.The unibody mouse as recited in claim 40 further including an onboardfeedback system configured to provide feedback to the user of the mouseso that the user is able to positively confirm that an action hasresulted in an actual activation of one or the input mechanisms of themouse.
 43. The unibody mouse as recited in claim 42 wherein the unibodymouse includes one or more audio feedback generators, haptics generatorsand visual feedback generators.
 44. A mouse, comprising: anelectronically controlled feedback system configured to provide feedbackto the user of the mouse so that the user is able to positively confirmthat an action has resulted in an actual activation of one or more inputmechanisms of the mouse.
 45. The mouse as recited in claim 44 whereinthe feedback system includes an audio feedback generator.
 46. The mouseas recited in claim 45 wherein the audio feedback generator is a piezoelectric speaker configured to output a clicking noise when a userperforms an action with at least one of the input mechanisms.
 47. Themouse as recited in claim 44 wherein the feedback system includes ahaptics mechanism configured to output a vibration when a user performsan action with at least one of the input mechanisms.
 48. The mouse asrecited in claim 44 wherein the feedback system includes a visualfeedback generator configured to output visual stimuli at the mouse whena user performs an action with at least one of the input mechanisms. 49.The mouse as recited in claim 48 wherein the visual feedback system isbased on light or electronic inks.
 50. The mouse as recited in claim 44wherein the input mechanisms are selected from touch sensors, forcesensors, and jog balls.
 51. A mouse method, comprising: monitoringpressure at the surface of a mouse; performing an action based on achange in pressure at the surface of the mouse.
 52. The method of claim51 wherein the action includes tiling and scaling down all open windowsin a display screen.
 53. The method of claim 51 wherein the actionincludes tiling and scaling down open windows associated with aparticular application in a display screen.
 54. The method of claim 51wherein the action includes moving all open windows to the edges of adisplay screen.
 55. The method of claim 51 wherein change in pressure iscause by squeezing the sides of the mouse.
 56. A mouse method,comprising: monitoring a force at a surface of a mouse; determiningwhether the mouse has been lifted off a surface; if the mouse has notbeen lifted off the surface, determining if a first force threshold hasbeen exceeded, and reporting a button event signal when the force isabove the first force threshold; if the mouse has been lifted off thesurface, determining if a second force threshold has been exceeded, andreporting the button event signal when the force is above the secondforce threshold.
 57. A mouse method, comprising: monitoring pressure atmouse surface; determining if a squeeze gesture is performed; and if asqueeze gesture is performed, performing an action in a windowmanagement program based on the pressure at the mouse surface.
 58. Amouse method, comprising: monitoring a left touch sensor; monitoring aright touch sensor; monitoring a switch; reporting a left button eventwhen only the left sensor and switch are activated; reporting a rightbutton event when only the right sensor and switch are activated;reporting a button event when the right sensor, left sensor and switchare activated, the button event being selected from a left button event,a right button event, a third button event, or simultaneous left andright button events.
 59. A mouse method, comprising: detecting a touchat a surface of a mouse; differentiating whether the touch is a light orhard touch; performing a first action when a touch is a light touch; andperforming a second action when a touch is hard touch.